DE1462107B2 - Arrangement for recording video signals containing synchronizing signals - Google Patents

Description

Sator of the clamping circuit has one of the diodes in the charging circuit connected in parallel with a high resistance Resistance value included.

In the drawing, the invention is illustrated using two preferred exemplary embodiments. It shows

Fig. 1 is a block diagram for the structure of a recording arrangement designed according to the invention as a whole,

F i g. FIG. 2 shows a basic circuit diagram for the clamping circuit in the frequency modulator of the arrangement from FIG Fig.l,

F i g. 3 shows an equivalent circuit diagram for the clamping circuit from FIG. 2,

Fig. 4 is a ¹ -ausführliches circuit diagram for the clamp circuit according to the g i in F. 2 illustrated principle and

F i g. 5 is a graph showing the operation of the clamping circuits from F i g. 3 and 4.

In the recording arrangement of FIG. 1 feeds a television camera 1 via a video amplifier 2 to a frequency modulator 4 with video signals containing synchronization signals. The frequency modulator 4 is also connected to an oscillator 3 operating at a frequency J ₁ and emits a frequency-modulated carrier signal at its output, which passes via a first filter 5 and an amplifier 6 to a mixer 8, which is also sent to a mixer 8 with a frequency / ₂ working oscillator 7 'is connected. The mixer 8 in turn feeds, via a second filter 9 and an amplifier 10, a write head 11 which records the video signals supplied by the television camera 1 on a magnetic tape 12.

The frequency modulator 4 contains a clamping circuit as shown in principle in FIG. 2 is shown. This clamping circuit is connected to an input terminal 23 with the video signals 24 from the television camera 1, which in addition to the actual image signal with a white level peak, a synchronization signal contain. The video signals 24 pass from the input terminal 23 to a capacitor 25 and charge it, the time constant for this capacitor charging by one in the charging circuit for the capacitor 25 lying diode 26 is determined. This diode 26 is in each case at the white level peak of the video signal 24 conductive, provided that this is the voltage present on the capacitor when it arrives 25 exceeds, and so each causes a charging of the capacitor 25 to the value of one such higher white value peak.

In the equivalent circuit of FIG. 3, the diode 26 can therefore be represented by a switch with is in series with a relatively small resistor. This resistor, the. the forward resistance the diode 26 represents in the conductive state is relatively small and it determines in conjunction with the size of the capacitor 25 itself the time constant for its charging, which therefore takes place relatively quickly.

Following the white level peak in video signal 24, diode 26 is non-conductive, switch S in the equivalent circuit diagram of FIG. 3 is therefore open and the capacitor 25 can only discharge via a resistor 27 connected in parallel to the diode 26, which is very large compared to the forward resistance r of the diode 26, so that the time constant for the discharge circuit formed by the resistor 27 for the capacitor 25 becomes relatively large and the capacitor discharge is therefore slow.

Each time a video signal 24 arrives with the current capacitor voltage am Capacitor 25 exceeding the white value peak at the input terminal 23 of the clamping circuit the diode 26 conducts, and the capacitor 25 is set to the value of this white value peak with a small time constant charged. This is followed by a slow capacitor discharge across the resistor 27, until a white value peak that exceeds the currently applied capacitor voltage again occurs in a video signal 24.

When the diode 26 is conductive, the voltage drop across the diode 26 is very small; In this case, practically the same potential prevails at the anode of the diode 26, which is connected to an output line 28, as at its cathode. This in turn is kept at a fixed potential, this fixed potential being determined by a wiper of a potentiometer 29, which is grounded via a bridging capacitor 31 and which in turn is connected between ground and the positive pole 30 of a DC voltage supply + B.

The on the output line 28 of the clamp circuit in FIG. 2 appearing video signals 32 are that is, clamped to a fixed value in their white value peak, and there is only one shift for the potential of the synchronization signals contained therein, as shown in FIG. 2 indicated by dashed lines is, for video signals 32 with a lower overall amplitude.

In the circuit diagram of FIG. 4 is to an input terminal 33 via a Coupling capacitor 34 connected to the base of a transistor 35, which is biased via a Voltage divider from two resistors 36 and 37 is obtained, of which resistor 36 is connected to ground while the resistor 37 connects to a DC voltage supply 38. The emitter of the transistor 35 is grounded via a resistor 39, while its collector via a resistor 40 is connected to the DC voltage supply 38. To the collector of transistor 35 the base of another transistor 41 of the opposite conductivity type is also connected, its collector to the emitter of transistor 35 and its emitter via a resistor 42 is connected to the DC voltage supply 38.

The transistors 35 and 41 together form a signal source with a low output impedance and generate a video signal similar to the one at input terminal 33 and transmitted through amplifier 2 from F i g. 1 supplied video signal.

This video signal now becomes one according to the principle of FIG. 2 built clamp circuit supplied. This contains one connected to the emitter of transistor 35 and the collector of transistor 41, respectively Capacitor 43, from which an output line 44 goes off, which is connected via a parallel circuit from a Diode 46 and a resistor 45 is connected to the wiper of a potentiometer 47, which also is grounded via a bypass capacitor 48. The potentiometer 47 itself is between Earth and a resistor 49 connected to the DC voltage supply 38.

5 6

meter 47 is also a Zener diode 50 parallel video signal changes, so changes the

switched, which is used to regulate the voltage. Capacity of diodes 53, 54 and 55, from which

The operation of the clamping described above - a change for the delay and the frequency circuit follows the same principle as the clamping of the signal on line 52 results,
circuit of FIG. 2. As soon as the white level peak 5 The frequency relationships for the circuit according to a video signal supplied to the capacitor 43 in FIG. 4 are illustrated in FIG. It shows whose current voltage exceeds the line A in FIG. 5 the frequency spectrum of a conductive at ode 46 and then holds the potential for the video signal output line 44 applied to the _{input terminal} 33 at the value determined by the wiper of the potentiometer 47 with a maximum frequency f nwx, for example. The through-io 3.5 MHz. Line B then shows the signal on the let resistance of diode 46, however, line 52 is large enough in relation to this video signal to show a deterioration in the details of the video, again showing the corresponding frequency spectrum signal during the direct current feedback . You can see that the lower limit of the hinder. The capacitor 43 discharges through a main component of the frequency-modulated signal of the diode 46 parallel-connected resistor 45, the 15 on line 52 in line B of FIG from in a module signal to be described below. This frequency-modulated signal lationskreis lying further diodes. This is then the filter 5 in FIG. 1 and the output signal for the capacitor 43 forming the discharge circuit is preferably selected after amplification in such a way that a time _{of 250 milliseconds through the mixer 8 with the frequency / 2} constant of 250 milliseconds for the condensers - of the oscillator 7 mixed. The frequency / ₂ can result in dasator discharge, so that the charge of the con is, for example, 51 MHz. The lower capacitor from one line interval to the next in the limit for the shifted carrier signal frequency can remain approximately constant, but the circuit can still be, for example, at 2MHz, while the upper limit for a reduction in the white value of its trailing upper limit can be 4 MHz,
led video signal can respond. As line B in Fig. 5 shows, this can be in the

The output line 44 thus carries a video video signal contained synchronizing signal depending on

signal, whose white value peak is essentially as large as that of the white value peak of the video signal

borrowed constant value is bracketed by the right or left shift, but there is none

Position of the wiper on potentiometer 47 determines 30 overmodulation for the image content of the video signal,

will. and there are also no disturbing beatings

The video frequencies come from the output line 44. In addition, since no white level clipper and signal to a variable delay circuit, no compression are required, one of the outputs is also in a feedback loop that contains a drawn linearity for the recorded signal transistor 51, which achieves a 35 via a line 52. Furthermore, for images with dark oscillator OSC, a frequency-modulated voltage learns the background and supplies corresponding light areas. The output line 44 with the cathode video signals is a high resolution for the detailed three diodes 53, 54 and 55 with variable cable reproduction in the light areas. Finally -can be connected to capacity. The anodes of the di- and the carrier drift during the playback are desolated 53 and 54 via an induction coil 56 and the 40 is reduced.

Anodes of the diodes 54 and 55 connected to one another via an induction A practical embodiment for a switching coil 57. In addition, the direction according to FIG. 4 with numerical data for the single anode of the diode 54 with the line 52 to the oscilloscope components is connected in the following table lator OSC , while to the anode the compiled:
Diode 55 is the collector of transistor 51 45 ~, _r ,, .-> " _n *,., * <

is closed. The anode of diode 53 finally S? ⁰¹⁸ * ^? 0.2 microfarads

is connected to a line 59 via a resistor 58, ^ ide "! ^ in : L ^ -, ^g Λ

via an induction coil 60 with a DC voltage resistance of 47 ... 10 kiloohm

voltage supply38 is connected and via bridging capacitor 48 .. 10 microfarads

a capacitor 61 is grounded The anode of the ₅ o resistor 49 560 ohms

Diode 53 is also through a capacitor 62 resistor 58 220 ohms

connected to the base of transistor 51, and from induction coil 60 20 microhenry

corresponding connection point leads a resistor capacitor 61 0 05 microfarads

stand63 to Leitung59 and a resistor 64 to S ^ ^{en? sat} ? lf ^{2 v} 2 picofarad

Earth. The emitter of the transistor 51 is via a ₅₅ ^W ^ ^erStan ^ f. '■

Capacitor 65 and a resistor 66 with ground resistor 64? λ

tied together. Bondens ator 65 100 P, cofarad

The capacitor 62, the resistors 58 and 63 resistor 66 1 kiloohra

and the resistors 61 and 64 form jointly, if necessary, between the output line

a feedback loop, and if the Po- 60 44 and ground are an additional capacitor with both-

potential of the output line 44 as a result of which, for example, 50 picofarads can be inserted.

1 sheet of drawings

Claims (3)

1 2 black shoulder, i.e. the synchronization signal in the claims: video signal. With the previously known recording arrangements 1. Arrangement for recording synchronizations of the type mentioned at the beginning is made with reverse signals containing video signals on 5 sees the above-mentioned band limit a a magnetic recording medium with clamping of the video signals to be recorded an input-side frequency modulator to the porch, i.e. the lowest amplitude, Modulation of the video signals to be recorded, made to avoid a failure in this the synchronization signals over the mixer, filter and amplifier with amplitude range is connected to a write head, thereby avoiding io. With this type of bracketing is however characterized in that the frequency modulus inevitably for video signals with a high proportion of white lator (4) has a clamping circuit, which is connected to a considerable loss of information, the Contains capacitor (23; 43), which on the one hand leg over themselves in the form of corresponding image distortions Charging circuit (26; 46) with a small time constant makes noticeable, which cause considerable disturbances in the image chargeable and then via a discharge impression. ■ -. circle (27; 45) can be discharged with a large time constant. The invention is therefore based on the object of forming a highest and the respective white recording arrangement of the initially mentioned peak in the video signal corresponding frequency th type so that with full upright one through the video signals to be recorded Maintaining the synchronization reliability, which is avoided with frequency-modulated carrier signals on an upper limit frequency that can be observed in the known arrangements for the frequency band of video signals that can be recorded on the incident or distortions in the upper white area of the drawing medium. _r level corresponding approximately holds until This object is according to the invention overall characterized (subsequent white level peak in the video signal a solves that the frequency modulator has a clamping scarf exceeded then straight adjoining 25 processing, which includes a capacitor, the level causes. one hand via a Loading circuit with small time con- 2. Arrangement according to claim 1, characterized by constant charging and then via a discharge, indicates that the charging circuit for the condensing circuit can be discharged with a large time constant and Sator (25; 43) of the clamping circuit a diode so a highest and the respective white value peak in (26; 46) contains, each of the 30 video signal corresponding frequency is exceeded by the The capacitor voltage is frequency-modulated by a white level video signal to be recorded The tip of a video signal becomes conductive and then a carrier signal at an upper limit frequency a capacitor charge on this white for the recordable on the recording medium value peak triggers the corresponding value. Frequency band approximately fixed level corresponding to 3. Arrangement according to claim 2, characterized in that it is held until a subsequent white level peak in the video indicates that the discharge circuit for the Kon-signal has exceeded the then currently applied capacitor (25; 43) of the clamping circuit causes one of the levels. Diode (26; 43) connected in parallel in the charging circuit. Resistance (27; 45) of high resistance value arrangement is therefore different from the previous one contains. 4 ° known arrangements not the black shoulder, but the maximum white value of the drawing video signal in brackets. To this In this way, the recordable frequency band is exceeded due to white value peaks in the C. The invention relates to an arrangement for avoiding the video signal for sure, and it comes draw from video signals containing synchronizing signals not to those in the known arrangements on a magnetic record- ing distortions or failures in the white ' The input medium has a frequency range for the recorded images on the input side. Any modulator for modulating the loss of sync signal information to be recorded, the all video signals, the mixer, filter and amplifier 50 if there is an abrupt transition from one to one is connected to a print head. image to be drawn with a very dark background In known arrangements of this type, such an image takes place with a very light background Recording of the video signals can occur with the help of a the video signals to be recorded frequency-modulus pulse shaping when playing back the recorded video signals Carrier. Examples of such arrangements 55 could easily compensate for video signals, since the are in U.S. Patent 3,040,125 and in sync signal when recording never up to »Rundfunktechnische Mitteilungen«, year 4, in the area of, for example, tape noise 1960, pp. 113 to 129 and 222 to 231. noise level caused by a magnetic tape With this recording method the result is now sinks. a limitation by the width of the magnet 60 In a preferred embodiment of the table The recording medium processable invention contains the charging circuit for the capacitor quenzbandes, when it is exceeded upwards the clamping circuit a diode, which in each case at or below the corresponding modulation frequencies exceeding the current capacitor spans can no longer be recorded and therefore for voltage through the white value peak of a video signal the reproduction of the recorded video signals 65 becomes conductive and then a capacitor charge fail. This risk of being exceeded is in each case for the value corresponding to this white value peak the top or bottom modulation frequency triggers. In a further embodiment of the invention zen given that the white value peak or can also be the discharge circuit for the condensation